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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Ankle-brachial index is associated with vascular calcification in pre-dialysis Chronic kidney disease patients

January 2018 (has links)
archives@tulane.edu / Background Ankle brachial index (ABI) is a noninvasive measure of subclinical cardiovascular disease (CVD) and atherosclerosis of the lower extremities. Low and high levels of ABI are associated with cardiovascular mortality and vascular calcification in dialysis chronic kidney disease (CKD) patients. However, the association of the spectrum of vascular calcification with low and high ABI is not well studied in pre-dialysis CKD patients. The purpose of this study is to investigate the association of both low and high ABI with the risk of vascular calcification in CKD patients. Methods We recruited 243 patients with pre-dialysis CKD from the great New Orleans area between 2010 and 2012. Our study used a cross-sectional design with ABI and CAC measured at the same visit. Continuous ABI measurements were taken and further classified into four categories : <=0.9 (low ABI) >0.9-<1.0 (borderline), 1.0-<1.4 (normal), >=1.4 (high). Level of vascular calcification were considered as the outcome and calculated by agatston score. Three categories of CAC is defined as: CAC agaston score=0, 0-100, >100. Three cumulative logit models were applied to the data. The first is an unadjusted univariate model, the second adjusts for baseline demographics, and the third adjusts for baseline demographics and covariates that are associated with CAC. Logistic regression methods were used to calculate the odds ratio of having a higher CAC score for CKD patients. Results We found a significant association between ABI and vascular calcification. All three models returned consistently significant result (p=0.0005, 0.0005, 0.0037, respectively) for the association between ABI and CAC. In addition, low ABI (ABI≤0.9) is also associated with an increased risk of CAC and severe CAC (OR=6.183, 95%CI(1.085, 35.228)). High ABI (>1.4) is also associated with an increase in CAC and severe CAC (OR=5.064, 95%CI (1.696, 15.122)). Borderline ABI (0.9<ABI<1.0) is not associated with an increase in CAC or severe CAC (OR=2.704, 95% CI (0.702, 10.418). Conclusion Compared to normal ABI level, low and high ABIs are both significantly associated with an increased risk of coronary artery calcification and severe coronary artery calcification in CKD patients. / 1 / Shuo Bai
2

Ankle Brachial Index Measurement in Primary Care Setting: How Long Does It Take?

Pearson, Tamera, Kukulka, Gary, Ur Rahman, Zia 01 November 2009 (has links)
Background: Peripheral arterial disease (PAD) affects over 8 million people in the United States and has been found to be associated with an increased incidence of coronary and carotid artery disease. The ankle brachial index (ABI) measurement is a highly specific noninvasive screening and diagnostic test for PAD, but is rarely performed in primary care office settings. This study sought to determine the actual performance time involved in completing an ABI in a primary care office. Methods: Data were collected by one provider on a convenience sample of women who met the inclusion criteria. The time was recorded at the beginning and upon the completion of the ABI procedure for each patient. Analysis of the time data was completed and barriers to performing the ABI were recorded by the provider. Results: The average time to complete an ABI was 5 minutes, with a range of 3-11 minutes. In 83.8% of patient encounters, the ABI procedure took less than 6 minutes to complete. Barriers identified by the provider included the additional time needed to explain the test and assist patients into the proper testing position. Conclusions: The actual performance time for an ABI in a primary care setting takes an average of 5 minutes, but additional time may be required for patient preparation and education. With proper scheduling and training, the ABI can be completed in a timely manner. The ABI is an important screening/diagnostic test that can be performed in primary care and potentially impact patient treatment plans.
3

Ankle Brachial Index as a Prognostic Tool for Women With Coronary Artery Disease

Pearson, Tamera Lea 01 January 2010 (has links)
Background and objectives: Coronary artery disease (CAD) is the leading cause of death among women both nationally and internationally. Despite increased knowledge regarding CAD in women, early diagnosis remains a difficult clinical task. A correlation between peripheral arterial disease (PAD) and CAD has been noted in previous research; however, these studies were either retrospective or did not focus on women. This research investigates the correlation of ankle brachial index (ABI), measurements used to diagnose PAD, and presence of CAD in women, in an effort to determine the predictive value of ABI specifically in women. Subjects and methods: A prospective correlation design was used to study women (n = 30) who were undergoing a diagnostic cardiac catheterization. Ankle brachial index readings were obtained prior to the catheterization procedure. Catheterization findings were grouped according to absence of CAD or presence of 1-vessel or multivessel CAD and coupled with each woman's ABI and recorded cardiovascular risk factors. Results: Peripheral arterial disease (based on ABI of <0.90 mm Hg) was found in 13.3% of the women. A significant correlation was found between ABI of less than 0.90 mm Hg and increasing age (t = -2.30, P =.029). Coronary artery disease was found in 82.1% of the women; more than half (57.1%) had multivessel disease. Absence of CAD was noted in 17.9%. Women with CAD were older than women without CAD (F = 3.86, P =.035). No significant differences were found between presence or absence of PAD based on ABI and diagnosis of no coronary disease or 1-vessel or multivessel coronary disease. Conclusions: This study failed to show the expected correlation between ABI of less than 0.90 mm Hg and CAD, but did show a significant correlation of age with presence of both PAD and CAD. Further research that focuses specifically on women is needed and should include a larger sample, additional unique cardiovascular risk factors, and innovative diagnostic tests to determine presence of CAD in women early in the disease process.
4

RELATIONSHIP OF INFRAGENICULAR ARTERIAL PATENCY WITH ANKLE-BRACHIAL INDEX AND TOE-BRACHIAL INDEX IN CRITICAL LIMB ISCHEMIA

Bunte, Matthew C. 11 June 2014 (has links)
No description available.
5

Prevalence of low and abnormal Ankle-Brachial index and their association with traditional risk factors in a multi-ethnic adult general practice population

Ingoe, J.C., Scally, Andy J., Kain, K. January 2011 (has links)
No
6

Att mäta ankeltryck i primärvården : Distriktssköterskors och distriktsläkares uppfattningar om en undersökningsmetod och dess användning

Bahri, Kristin January 2012 (has links)
Background: Peripheral arterial disease (PAD), as a consequence of atherosclerosis in the arteria of the limbs, affects one of ten Swedes older than 65. PAD can develop slowly and silently, and involves an increased risk for cardiac infarction and stroke. Measurement of the patient´s ankle blood pressure and calculation of the ankle-brachial index is an evidence-based method to discover PAD. Objective: To investigate how district nurses and general practitioners perceive this method of examination and experience possible obstacles to why it is not more commonly applied at primary health care centres. Method: Data collected by semi-structured interviews have been processed by qualitative content analysis with a manifest onset. Results: The participants described a lack of routine for the measurement of ankle blood pressure at their health care centres. In their experience the cooperation of district nurses and general practitioners was characterized by insufficient information and unclear roles. Conclusion: As a consequence of lacking routines and indistinct roles at the health care centres, measurement of ankle blood pressure was not always performed as indicated in the guidelines. More knowledge and established routines could have led to better care for patients with PAD. / Bakgrund: Perifer artärsjukdom till följd av ateroskleros (åderförfettning eller åderförkalkning) i benens pulsådror drabbar en av tio svenskar över 65 år. Sjukdomen, som länge kan vara symtomfri, medför en ökad risk för hjärtinfarkt och stroke. Ankeltrycksmätning och beräkning av ankelbrakialindex är en evidensbaserad metod för att upptäcka perifer artärsjukdom. Syfte: Att beskriva hur distriktssköterskor och distriktsläkare uppfattade mätning av ankeltryck, beräkning av ankelbrakialindex och eventuella hinder för att använda metoden inom primärvården. Metod: Data samlades in med hjälp av semistrukturerade intervjuer och analyserades med hjälp av kvalitativ innehållsanalys med manifest ansats. Resultat: Informanterna upplevde att rutiner för att mäta ankeltryck saknades på deras vårdcentraler. I stället var det upp till informanterna själva att avgöra om och när de skulle mäta. Samarbetet kring patienterna mellan distriktsläkare och distriktssköterskor präglades av bristfällig information och oklara roller. Slutsats: Avsaknaden av rutiner och en otydlig rollfördelning ledde till att ankeltryck inte alltid mättes på de patienter som borde ha undersökts med hjälp av metoden. Bättre kunskaper och rutiner för ankeltrycksmätning i primärvården skulle kunna leda till säkrare vård för patienter med perifer artärsjukdom.
7

The Prevalence and Clinical Correlative Factors of Peripheral Arterial Disease in Patients with Chronic Kidney Disease

Yang, Ching-ping 17 June 2009 (has links)
Research Objective Patients with chronic kidney disease (CKD) are at increased risk for atherosclerosis and peripheral artery disease (PAD). PAD has received far less attention than coronary artery disease (CAD) in CKD patients. Few studies have examined risk factors for PAD in CKD. We studied the possible related risk factors and benefit of hypertension treatment in CKD patients with PAD. Data Sources We included 129 patients of both sexes with stages 3 to 5 of CKD, as described by the Kidney Outcome Quality Initiatives (K/DOQI ) classification, without receiving dialysis therapy, not previously diagnosed with PAD. Study Design The following information were collected within six month period, including demographic characteristics, history of hypertension, anti-hypertension drug, diabetes, smoking, and pre-existing cardiovascular disease, body mass index (BMI), fasting blood glucose, HbA1c, total cholesterol, triglyceride(TG), high density lipoprotein cholesterol (HDL), low density lipoprotein cholesterol(LDL), calcium (Ca), phosphate(P), Albumin, uric acid, urine protein. Ankle-brachial index (ABI) is a noninvasive diagnostic test that is efficient in detecting asymptomatic PAD with ABI <0.9. Findings There were 22 (17.7 %) participants with PAD. Higher systolic blood pressure (SBP), higher diastolic blood pressure (DBP), higher pulse pressure showed strong association with PAD in CKD patients. On further analysis, significant fewer patients treated with calcium channel blocker (CCB) in hypertensive CKD patients with PAD (£q2 =7.055, p =0.008). The multivariate logistic regression analysis in hypertensive patients demonstrated the risk factors for PAD was pulse pressure, and Calcium channel blocker treatment may correlate with decreasing PAD formation (odds ratio= 0.232, 95% CI=0.07-0.73, p =0.013) in CKD patients. Conclusion There is a high prevalence rate of PAD in population of CKD, especially those with hypertension. ABI should be routinely examined in these patients who can benefit earlier from therapeutic measures.
8

Correlation of Ankle-Brachial Index Values With Carotid Disease, Coronary Disease, and Cardiovascular Risk Factors in Women

Pearson, Tamera Lea 01 November 2007 (has links)
BACKGROUND: Recent studies indicate that the use of ankle-brachial index (ABI) measurements helps identify patients with peripheral arterial disease. Previous research also reveals a relationship between peripheral arterial disease and higher incidence of cardiac mortality and morbidity. PURPOSE: The purpose of this study was to investigate the correlation of a low ABI (<0.90 mm Hg) with coronary artery disease, diabetes, hypercholesterolemia, body mass index greater than 25, a sedentary lifestyle, smoking, and carotid artery disease. METHODS: A descriptive correlational design was used to study a population (N = 810) of fairly healthy women who self-selected to undergo cardiovascular screening that they paid for out of pocket. Cardiac disease and most of the data on risk factors were obtained using questionnaires. Carotid artery stenosis was determined by ultrasound. Hypotheses were tested using χ and independent t test. RESULTS: A statistically significant relationship was found between a low ABI and the presence of moderate to severe carotid artery stenosis (χ = 5.90, P = .015). A low ABI (<0.90 mm Hg) was not significantly related to cardiac disease (χ = 0.83, P = .362), diabetes (χ = 1.82, P = .177), hypercholesterolemia (χ = 0.01, P = .930), claudication (χ = 2.06, P = .151), physical activity (χ = 1.17, P = .884), or body mass index (t = 1.12, P = .270). CONCLUSION: The significant relationship between low ABI and carotid artery stenosis illustrates that atherosclerosis occurs in multiple arterial beds simultaneously. The lack of association between ABI and the other variables probably reflects the self-report nature of the data collected on these variables. Ankle-brachial index measurements may be useful in future research as a tool for early recognition of cardiovascular disease.
9

Associação entre diferentes parâmetros de variabilidade da pressão sistólica fornecidos pela monitorização ambulatorial de pressão arterial (mapa) e o índice tornozelo-braquial

Wittke, Estefania Inez January 2009 (has links)
Introdução: Tem sido demonstrada uma associação entre a variabilidade da pressão arterial avaliada por diferentes índices e lesão em órgão-alvo, independentemente dos valores de pressão arterial. O índice tornozelo-braquial (ITB) é útil no diagnóstico de doença arterial oclusiva periférica, sendo reconhecido como marcador de aterosclerose sistêmica. Objetivo: Avaliar a associação entre três diferentes métodos de estimar a variabilidade da pressão arterial sistólica (taxa de variação da pressão no tempo - índice "time-rate", coeficiente de variabilidade, desvio padrão das médias da pressão arterial sistólica de 24 horas) e o índice tornozelo-braquial (ITB). Métodos: Em um estudo transversal, pacientes atendidos no ambulatório de hipertensão realizaram medida de ITB e Monitorização Ambulatorial da Pressão Arterial de 24 horas (MAPA). Três parâmetros de variabilidade foram avaliados: o índice "time-rate" definido como a primeira derivada da pressão arterial sistólica em relação ao tempo; desvio padrão (DP) das médias da pressão arterial sistólica (PAS) de 24 horas e coeficiente de variabilidade (CV=DP/média pressóricaX100%). O ITB aferido por doppler foi obtido pela razão entre a maior pressão arterial sistólica do tornozelo ou pediosa e a maior pressão sistólica dos braços. O ponto de corte para o diagnóstico de doença arterial periférica foi ITB <= 0,90 ou>= 1,40. Resultados: A análise incluiu 425 pacientes: 69,2% eram do sexo feminino, com idade média de 57±12 anos, 26,1% eram tabagistas e 22,1% tinham diabetes mellitus. ITB alterado foi detectado em 58 pacientes (13,6%). Para os grupos ITB normal e anormal o índice "time-rate", DP das médias e CV foram: 0,469±0,119 mmHg/min e 0,516± 0,146 mmHg/min (p=0,007); 12,6±3,7 mmHg e 13,2±4,7 mmHg (p=0,26); 9,3±2,9% e 9,3±2,6 % (p=0,91), respectivamente. No modelo de regressão logística, o "time-rate" foi associado com ITB, independentemente da idade (RR=6,9; 95% IC= 1,1-42,1; P=0,04). Em modelo de regressão linear múltipla demonstrou-se uma associação independente da idade, PAS de 24 horas e presença de diabetes mellitus. Conclusão: O índice "time-rate" foi o único parâmetro de variabilidade da pressão arterial sistólica associado com índice tornozelo-braquial e pode ser utilizado na estratificação de risco em hipertensos. Este parâmetro de variabilidade obtido por método não invasivo deve ser melhor investigado em estudos prospectivos. / Introduction: An association between the Blood Pressure Variability, estimated by different indexes, and target-organ damage has been established independently of blood pressure levels. The Ankle-Brachial Index (ABI) is useful in the diagnosis of peripheral arterial disease and it is recognized as a cardiovascular risk marker. Purpose: To evaluate the association between three different methods in estimating the variability of systolic blood pressure (rate of change of pressure over time - time rate index, coefficient of variability, standard deviation of the average 24-hour systolic blood pressure) and the ankle-brachial index (ABI). Methods: In a cross-sectional study, patients of a hypertension clinic underwent ABI measurement and 24-hour Ambulatory Blood Pressure Monitoring (ABPM). Variability was estimated according to three parameters: the time rate index, defined as the first derivative of systolic blood pressure at the time; standard deviation (SD) of 24-hour systolic blood pressure (SBP); and coefficient of variability of 24-hour SBP (CV = SD / mean value X 100%). The ABI was measured by Doppler and obtained by dividing the systolic blood pressure on the ankle or foot (whichever was higher) by the higher of the two systolic blood pressures on the arms. The cutoff point for diagnosis of peripheral arterial disease was ABI<= 0.90 or>= 1.40. Results: The analysis included 425 patients: 69.2% were female, mean age was 57±12 years, 26.1% were current smokers and 22.1% diabetics. Abnormal ABI was detected in 58 patients (13.6%). For the normal and abnormal ABI groups the time rate index, the average SD and CV were 0.469 ± 0.119 mmHg/min and 0.516 ± 0.146 mmHg/min (p = 0.007), 12.6±3.7 mmHg and 13.2±4.7 mmHg (p = 0.26), 9.3±2.9% and 9.3±2.6% (p = 0.91), respectively. In the logistic regression model, time rate was associated with ABI, regardless of age (RR = 6.9, 95% CI = 1.1- 42.1; P = 0.04). The multiple linear regression model showed an association that was independent of age, 24-hour SBP and presence of diabetes. Conclusion: The time rate index was the only measurement of variability of systolic blood pressure associated with ankle-brachial index, and might be used for risk stratification in hypertensive patients. This measurement of variability was obtained by a non-invasive method and should be better investigated in prospective studies.
10

Associação entre diferentes parâmetros de variabilidade da pressão sistólica fornecidos pela monitorização ambulatorial de pressão arterial (mapa) e o índice tornozelo-braquial

Wittke, Estefania Inez January 2009 (has links)
Introdução: Tem sido demonstrada uma associação entre a variabilidade da pressão arterial avaliada por diferentes índices e lesão em órgão-alvo, independentemente dos valores de pressão arterial. O índice tornozelo-braquial (ITB) é útil no diagnóstico de doença arterial oclusiva periférica, sendo reconhecido como marcador de aterosclerose sistêmica. Objetivo: Avaliar a associação entre três diferentes métodos de estimar a variabilidade da pressão arterial sistólica (taxa de variação da pressão no tempo - índice "time-rate", coeficiente de variabilidade, desvio padrão das médias da pressão arterial sistólica de 24 horas) e o índice tornozelo-braquial (ITB). Métodos: Em um estudo transversal, pacientes atendidos no ambulatório de hipertensão realizaram medida de ITB e Monitorização Ambulatorial da Pressão Arterial de 24 horas (MAPA). Três parâmetros de variabilidade foram avaliados: o índice "time-rate" definido como a primeira derivada da pressão arterial sistólica em relação ao tempo; desvio padrão (DP) das médias da pressão arterial sistólica (PAS) de 24 horas e coeficiente de variabilidade (CV=DP/média pressóricaX100%). O ITB aferido por doppler foi obtido pela razão entre a maior pressão arterial sistólica do tornozelo ou pediosa e a maior pressão sistólica dos braços. O ponto de corte para o diagnóstico de doença arterial periférica foi ITB <= 0,90 ou>= 1,40. Resultados: A análise incluiu 425 pacientes: 69,2% eram do sexo feminino, com idade média de 57±12 anos, 26,1% eram tabagistas e 22,1% tinham diabetes mellitus. ITB alterado foi detectado em 58 pacientes (13,6%). Para os grupos ITB normal e anormal o índice "time-rate", DP das médias e CV foram: 0,469±0,119 mmHg/min e 0,516± 0,146 mmHg/min (p=0,007); 12,6±3,7 mmHg e 13,2±4,7 mmHg (p=0,26); 9,3±2,9% e 9,3±2,6 % (p=0,91), respectivamente. No modelo de regressão logística, o "time-rate" foi associado com ITB, independentemente da idade (RR=6,9; 95% IC= 1,1-42,1; P=0,04). Em modelo de regressão linear múltipla demonstrou-se uma associação independente da idade, PAS de 24 horas e presença de diabetes mellitus. Conclusão: O índice "time-rate" foi o único parâmetro de variabilidade da pressão arterial sistólica associado com índice tornozelo-braquial e pode ser utilizado na estratificação de risco em hipertensos. Este parâmetro de variabilidade obtido por método não invasivo deve ser melhor investigado em estudos prospectivos. / Introduction: An association between the Blood Pressure Variability, estimated by different indexes, and target-organ damage has been established independently of blood pressure levels. The Ankle-Brachial Index (ABI) is useful in the diagnosis of peripheral arterial disease and it is recognized as a cardiovascular risk marker. Purpose: To evaluate the association between three different methods in estimating the variability of systolic blood pressure (rate of change of pressure over time - time rate index, coefficient of variability, standard deviation of the average 24-hour systolic blood pressure) and the ankle-brachial index (ABI). Methods: In a cross-sectional study, patients of a hypertension clinic underwent ABI measurement and 24-hour Ambulatory Blood Pressure Monitoring (ABPM). Variability was estimated according to three parameters: the time rate index, defined as the first derivative of systolic blood pressure at the time; standard deviation (SD) of 24-hour systolic blood pressure (SBP); and coefficient of variability of 24-hour SBP (CV = SD / mean value X 100%). The ABI was measured by Doppler and obtained by dividing the systolic blood pressure on the ankle or foot (whichever was higher) by the higher of the two systolic blood pressures on the arms. The cutoff point for diagnosis of peripheral arterial disease was ABI<= 0.90 or>= 1.40. Results: The analysis included 425 patients: 69.2% were female, mean age was 57±12 years, 26.1% were current smokers and 22.1% diabetics. Abnormal ABI was detected in 58 patients (13.6%). For the normal and abnormal ABI groups the time rate index, the average SD and CV were 0.469 ± 0.119 mmHg/min and 0.516 ± 0.146 mmHg/min (p = 0.007), 12.6±3.7 mmHg and 13.2±4.7 mmHg (p = 0.26), 9.3±2.9% and 9.3±2.6% (p = 0.91), respectively. In the logistic regression model, time rate was associated with ABI, regardless of age (RR = 6.9, 95% CI = 1.1- 42.1; P = 0.04). The multiple linear regression model showed an association that was independent of age, 24-hour SBP and presence of diabetes. Conclusion: The time rate index was the only measurement of variability of systolic blood pressure associated with ankle-brachial index, and might be used for risk stratification in hypertensive patients. This measurement of variability was obtained by a non-invasive method and should be better investigated in prospective studies.

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